Steps in the evolution of heteromorphic sex chromosomes

Charlesworth, Deborah; Charlesworth, Brian; Marais, Gabriel

doi:10.1038/sj.hdy.6800697

Cited by 843 publications

(870 citation statements)

References 107 publications

(113 reference statements)

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“…That constraint could be offset, however, if regions of sex chromosomes close to the SDR show reduced recombination per DNA base. Even limited recombination may protect these regions flanking the SDR from the rapid accumulation of rearrangements and repetitive sequences often seen within the nonrecombining regions of Y chromosomes (Charlesworth et al 2005). If so, these flanking regions may be a fruitful focus for empirical research.…”

Section: Discussionmentioning

confidence: 99%

Patterns of Neutral Genetic Variation on Recombining Sex Chromosomes

2010

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Many animals and plants have sex chromosomes that recombine over much of their length. Here we develop coalescent models for neutral sites on these chromosomes. The emphasis is on expected coalescence times (proportional to the expected amount of neutral genetic polymorphism), but we also derive some results for linkage disequilibria between neutral sites. We analyze the standard neutral model, a model with polymorphic Y chromosomes under balancing selection, and the invasion of a neo-Y chromosome. The results may be useful for testing hypotheses regarding how new sex chromosomes originate and how selection acts upon them.

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Section: Discussionmentioning

confidence: 99%

Patterns of Neutral Genetic Variation on Recombining Sex Chromosomes

2010

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“…In flowering plants, dioecy appears to have evolved from hermaphroditism on many separate occasions via gynodioecy or, more rarely, via androdioecy [4]. The existence of these transitional states implies that alleles causing male sterility and female sterility occur at separate loci [78].…”

Section: Initial Establishment Of the Non-recombining Regionmentioning

confidence: 99%

“…In mammals, for example, recombination between the sex chromosomes appears to have been suppressed through a combination of inversions, translocations and suppression of crossing over by local modifiers [4][5][6]. In mammals, birds and some flowering plants, genetic divergence between the sex chromosomes decreases with distance from the sex-determination locus, with discontinuities producing evolutionary strata [5,7,8].…”

Section: Introductionmentioning

confidence: 99%

“…In mammals, birds and some flowering plants, genetic divergence between the sex chromosomes decreases with distance from the sex-determination locus, with discontinuities producing evolutionary strata [5,7,8]. Although strata may be caused by variation in the rate of gene conversion along the sex chromosomes [4], they are usually interpreted as evidence that recombination has been restricted in several stages [5,6]. This suggests that non-recombining regions have gradually expanded through cumulative recombination-suppressing events.…”

Section: Introductionmentioning

confidence: 99%

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No amicable divorce? Challenging the notion that sexual antagonism drives sex chromosome evolution

Ironside¹

2010

BioEssays

119

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Ironside, J. E. (2010). No amicable divorce? Challenging the notion that sexual antagonism drives sex chromosome evolution. Bioessays, 32, (8), 718-726. IMPF: 04.47 RONO: 00Although sexual antagonism may have played a role in forming some sex chromosome systems, there appears to be little empirical or theoretical justification in assuming that it is the driving force in all cases of sex chromosome evolution. In many species, sex chromosomes have diverged in size and shape through the accumulation of mutations in regions of suppressed recombination. It is commonly assumed that recombination is suppressed in sex chromosomes due to selection to resolve sexually antagonistic pleiotropy. However, the requirement for a sex chromosome-specific mechanism for suppressing recombination is questionable, since more general models of recombination suppression on autosomes also appear to be applicable to sex chromosomes. Direct tests of the predictions of the sexual antagonism hypothesis offer only limited support in specific sex chromosome systems and circumstantial evidence remains open to interpretation.Peer reviewe

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“…(1 -3) To account for its evolution, several alternative hypotheses have been proposed to explain the driving forces of degeneration of the Y chromosomes that can occur as recombination with the X chromosome is increasingly blocked. (1,2,(4)(5)(6)(7) This problem has been discussed extensively by population geneticists and was not included in this review.…”

Section: Introductionmentioning

confidence: 99%

The Y chromosome as a target for acquired and amplified genetic material in evolution

2005

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SummaryThe special properties of the Y chromosome stem form the fact that it is a non-recombining degenerate derivative of the X chromosome. The absence of homologous recombination between the X and the Y chromosome leads to gradual degeneration of various Y chromosome genes on an evolutionary timescale. The absence of recombination, however, also favors the accumulation of transposable elements on the Y chromosome during its evolution, as seen with both Drosophila and mammalian Y chromosomes. Alongside these processes, the acquisition and amplification of autosomal male benefit genes occur. This review will focus on recent studies that reveal the autosome-acquired genes on the Y chromosome of both Drosophila and humans. The evolution of the acquired and amplified genes on the Y chromosome is also discussed. Molecular and comparative analyses of Y-linked repeats in the Drosophila melanogaster genome demonstrate that there was a period of their degeneration followed by a period of their integration into RNAi silencing, which was beneficial for male fertility. Finally, the function of non-coding RNA produced by amplified Y chromosome genetic elements will be discussed.

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Steps in the evolution of heteromorphic sex chromosomes

Cited by 843 publications

References 107 publications

Patterns of Neutral Genetic Variation on Recombining Sex Chromosomes

Patterns of Neutral Genetic Variation on Recombining Sex Chromosomes

No amicable divorce? Challenging the notion that sexual antagonism drives sex chromosome evolution

The Y chromosome as a target for acquired and amplified genetic material in evolution

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